Speech versus nonspeech in pitch memory

Semal, Catherine; Demany, Laurent; Ueda, Kazuo; Hallé, Pierre

doi:10.1121/1.416298

Cited by 67 publications

(67 citation statements)

References 17 publications

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“…Salame and Baddeley [1989] showed that vocal music interfered more strongly with phonological short-term memory than instrumental music, supporting the assumption of two independent WM systems for verbal and tonal stimuli [Salame and Baddeley, 1989]. On the other hand, results by Semal et al [1996] suggest that the pitch of speech sounds is not stored differently from the pitch of nonspeech sounds in WM. In addition, Iwanaga and Itoh [2002] reported that instrumental as well as vocal music interfered with a verbal WM task, and Chan et al [1998] observed that musical training increases the performance during a verbal WM task, suggesting rather overlapping neural resources for verbal and tonal WM.…”

Section: Introductionmentioning

confidence: 54%

Functional architecture of verbal and tonal working memory: An FMRI study

Koelsch

Schulze

Sammler

et al. 2008

Human Brain Mapping

277

274

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This study investigates the functional architecture of working memory (WM) for verbal and tonal information during rehearsal and articulatory suppression. Participants were presented with strings of four sung syllables with the task to remember either the pitches (tonal information) or the syllables (verbal information). Rehearsal of verbal, as well as of tonal information activated a network comprising ventrolateral premotor cortex (encroaching Broca's area), dorsal premotor cortex, the planum temporale, inferior parietal lobe, the anterior insula, subcortical structures (basal ganglia and thalamus), as well as the cerebellum. The topography of activations was virtually identical for the rehearsal of syllables and pitches, showing a remarkable overlap of the WM components for the rehearsal of verbal and tonal information. When the WM task was performed under articulatory suppression, activations in those areas decreased, while additional activations arose in anterior prefrontal areas. These prefrontal areas might contain additional storage components of verbal and tonal WM that are activated when auditory information cannot be rehearsed. As in the rehearsal conditions, the topography of activations under articulatory suppression was nearly identical for the verbal as compared to the tonal task. Results indicate that both the rehearsal of verbal and tonal information, as well as storage of verbal and tonal information relies on strongly overlapping neuronal networks. These networks appear to partly consist of sensorimotor-related circuits which provide resources for the representation and maintenance of information, and which are remarkably similar for the production of speech and song.

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Section: Introductionmentioning

confidence: 54%

Functional architecture of verbal and tonal working memory: An FMRI study

Koelsch

Schulze

Sammler

et al. 2008

Human Brain Mapping

277

274

View full text Add to dashboard Cite

show abstract

“…Musicians relied more on a combination of encoding techniques (either dual or multiple), including auditory (tone sound), verbal (labeling tones or contour patterns), and tactile (playing an imaginary instrument) encoding, whereas nonmusicians relied suggest that acoustic similarity impacts upon nonmusicians' immediate serial recall of both verbal and tonal pitch materials. This correspondence suggests support for a degree of shared storage in short-term memory (Salamé & Baddeley, 1989;Semal et al, 1996). It is still possible to postulate the existence of separate stores for verbal and pitch sequences (Berz, 1995;Deutsch, 1970;Pechmann & Mohr, 1992) but with the caveat that they operate using similar principles (i.e., storage of pitch sounds).…”

Section: Resultsmentioning

confidence: 95%

“…Deutsch (1970) found that irrelevant tones disrupted performance on tone recognition, but that irrelevant speech materials had little if any detrimental effect. Since that study however, several authors have reported a significant effect of background speech and music on memory for musical sounds (D. M. Jones, Macken, & Harries, 1997;Pechmann & Mohr, 1992;Semal & Demany, 1991, 1993Semal, Demany, Ueda, & Hallé, 1996). Semal et al concluded that the pitch dimension, whether it be music based or speech based, is the element that is commonly disruptive to both verbal and musical processing in short-term memory.…”

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confidence: 98%

Musicians' and nonmusicians' short-term memory for verbal and musical sequences: Comparing phonological similarity and pitch proximity

2010

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There is a long scientific tradition of examining the similarities between language and music (Darwin, 1871;Patel, 2008). Studying commonalities between how language and musical sounds are processed affords more opportunities to learn about how we interact with the auditory environment than are available from studying either domain in isolation (Callan et al., 2006;Koelsch et al., 2009;Kraus & Banai, 2007;Patel, 2009;Peretz & Zatorre, 2005;Wong, Skoe, Russo, Dees, & Kraus, 2007). In the present article, we compare the serial recall of speech and music from short-term memory.The first reason for choosing short-term memory for a language-music comparison is that much is known about the operation of auditory-verbal serial recall. For simplicity, we present our studies within a single broad theoretical framework-the multicomponent workingmemory model (Baddeley, 2000;Baddeley & Hitch, 1974)-although we acknowledge that they could be fitted into other frameworks developed to explain processing in short-term memory. The working-memory model comprises an attention-controlling central executive and three subsystems: the phonological loop, the visuospatial sketchpad, and the episodic buffer. The phonological loop is associated with the processing of speechlike information. It comprises a passive phonological store, which acts as a temporary holding center for speech-based information, and an articulatory rehearsal process, during which incoming visual information can be recoded and rehearsed using a phonological code (Baddeley, 2007). In the present research, we question whether the phonological loop also may be capable of processing musical stimuli.A second reason for focusing the language-music comparison within short-term memory is the importance of verbal short-term memory for a range of higher cognitive abilities. These include the acquisition of vocabulary and grammar (Baddeley, Papagno, & Vallar, 1988;Gathercole & Baddeley, 1990), reading (Baddeley, Gathercole, & Papagno, 1998), and action control (Baddeley, Chincotta, & Adlam, 2001;Liefooghe, Barouillet, Vandierendonck, & Camos, 2008;Miyake et al., 2000). An empirical investigation of language and music processing in shortterm memory therefore has the potential to encourage investigations into the role of musical short-term memory in equivalent domain cognitive abilities (e.g., reading music Language-music comparative studies have highlighted the potential for shared resources or neural overlap in auditory short-term memory. However, there is a lack of behavioral methodologies for comparing verbal and musical serial recall. We developed a visual grid response that allowed both musicians and nonmusicians to perform serial recall of letter and tone sequences. The new method was used to compare the phonological similarity effect with the impact of an operationalized musical equivalent-pitch proximity. Over the course of three experiments, we found that short-term memory for tones had several similarities to verbal memory, including limited capacity and a significant ...

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“…Although prior explanations of interference have advocated interitem confusion (e.g., Deutsch, 1984;Ruusuvirta et al, 2008), grouping (e.g., Jones et al, 1997), or general trace distortion (e.g., Semal et al, 1996) as the underlying causal mechanisms, TMM hypothesizes that interference results from feature overwriting and updating (McKeown & Wellsted, 2009;Mercer & McKeown, 2010). To test this possibility, listeners compared standard and comparison tones over a 10-sec interval.…”

Section: Discussionmentioning

confidence: 99%

“…Intuitively, it would appear that perceptually similar distractors can blur the memory of the standard, thereby distorting the accuracy of the trace (Pechmann & Mohr, 1992;Semal, Demany, Ueda, & Hallé, 1996), and Ruusuvirta et al (2002) have argued that the interfering tones bias the representation of the existing memory toward the frequency of the interfering event. Building on these ideas, Ruusuvirta et al (2008) asserted that interference is a consequence of interitem confusion.…”

mentioning

confidence: 99%

Updating and feature overwriting in short-term memory for timbre

Mercer

McKeown

2010

Attention, Perception & Psychophysics

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Previous research has demonstrated a potent, stimulus-specific form of interference in short-term auditory memory. This effect has been interpreted in terms of interitem confusion and grouping, but the present experiments suggested that interference might be a feature-specific phenomenon. Participants compared standard and comparison tones over a 10-sec interval and were required to determine whether they differed in timbre. A single interfering distractor tone was presented either 50 msec or 8 sec after the offset of the standard (Experiment 1) or 2 sec prior to its onset (Experiment 2). The distractor varied in the number of features it shared with the standard and comparison, and this proved critical, since performance on the task was greatly impaired when the distractor either consisted of novel, unshared features (Experiment 1) or contained the distinguishing feature of the comparison tone (Experiments 1 and 2). These findings were incompatible with earlier accounts of forgetting but were fully explicable by the recent timbre memory model, which associates interference in short-term auditory memory with an "updating" process and feature overwriting. These results suggest similarities with the mechanisms that underlie forgetting in verbal short-term memory.

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Speech versus nonspeech in pitch memory

Cited by 67 publications

References 17 publications

Functional architecture of verbal and tonal working memory: An FMRI study

Functional architecture of verbal and tonal working memory: An FMRI study

Musicians' and nonmusicians' short-term memory for verbal and musical sequences: Comparing phonological similarity and pitch proximity

Updating and feature overwriting in short-term memory for timbre

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